Voltage and temperature sensor for a serializer/deserializer communication application

ABSTRACT

The present invention relates to integrated circuits. More specifically, embodiments of the present invention provide methods and systems for determining temperatures of an integrated circuit using an one-point calibration technique, where temperature is determined by a single temperature measurement and calculation using known electrical characteristics of the integrated circuit.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 15/409,828, filed Jan. 19, 2017, which is a continuation of U.S. patent application Ser. No. 14/021,955, filed Sep. 9, 2013, now issued as U.S. Pat. No. 9,587,992 on Mar. 7, 2017, which is a continuation-in-part patent application to the U.S. patent application Ser. No. 13/802,219, filed Mar. 13 2013, now issued as U.S. Pat. No. 9,212,952 on Dec. 15, 2015, which is incorporated by reference herein for all purposes.

BACKGROUND OF THE INVENTION

The present invention relates to integrated circuits. More specifically, embodiments of the present invention provide methods and systems for temperature calibration and determination of an integrated circuit using a one-point calibration technique, where temperature is calibrated by a single temperature measurement and temperature determination is performed using known electrical characteristics of the integrated circuit.

Integrated circuits have proliferated through the years. As feature sizes become smaller, certain types of devices have become larger, leading to temperature related problems. That is, a large networking or processing device consumes a large amount of power, which is often dissipated as thermal energy such as heat. Heat is problematic and is desirably to be controlled and monitored. Unfortunately, conventional devices often lack suitable thermal sensing devices. That is, conventional temperature sensing devices are non-existent in many integrated circuit devices. At best, conventional sensing devices often use a diode device to monitor current information to extract temperature information from other non-integrated integrated circuit devices. The diode device is configured with an analog to digital convert to transmit the temperature information. The converter is often expensive, large, and difficulty to scale and manufacture in an efficient manner. Other limitations include difficulty in calibration, monitoring, and often require multi-point calibration, which leads to additional costs during the manufacture of the integrated circuit.

From the above, it is seen that techniques for improving temperature sensing and monitoring integrated circuits are highly desirable.

BRIEF SUMMARY OF THE INVENTION

The present invention relates to integrated circuits. More specifically, embodiments of the present invention provide methods and systems for determining temperatures of an integrated circuit using a one-point calibration technique, where temperature is determined by a single temperature measurement and calculation using known electrical characteristics of the integrated circuit.

Benefits are achieved over conventional techniques. Among other things, temperature calibration and determination can be performed by using measurements of corresponding electrical characteristics, such as voltage, current, delay, and/or others. Measuring electrical characteristics is usually faster and easier than measuring temperature. In addition, by using a single-point calibration method, the amount of time (which translates to manufacturing costs) of calibrating the temperature sensor is greatly reduced. It is to be appreciated that embodiments of the present invention are compatible with existing circuits and devices.

The present invention achieves these benefits and others in the context of known memory technology. However, a further understanding of the nature and advantages of the present invention may be realized by reference to the latter portions of the specification and attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The following diagrams are merely examples, which should not unduly limit the scope of the claims herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. It is also understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this process and scope of the appended claims.

FIG. 1 is a simplified block diagram of a system on a chip integrated circuit device according to an embodiment of the present invention.

FIG. 2 is a block diagram of a sensing device with a multiplexer according to an embodiment of the present invention.

FIG. 3 is a simplified flow diagram illustrating the operation of a sensing device according to embodiments of the present invention.

FIG. 4 is a simplified diagram illustrating a temperature sensor system according to an embodiment of the present invention.

FIG. 5 is a simplified flow diagram illustrating a process for calibrating a temperature sensor according to an embodiment of the present invention.

FIG. 6 is a simplified graph illustrating one point error calculation according to embodiments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to integrated circuits. More specifically, embodiments of the present invention provide methods and systems for determining temperatures of an integrated circuit using a one-point calibration technique, where temperature is determined by a single temperature measurement and calculation using known electrical characteristics of the integrated circuit.

An integrated circuits such as SerDes typically have multiple locations that may heat up to a temperature greater than the optimal operating temperature. In various embodiments, the present invention provides sensing techniques for measuring these locations. FIG. 1 is a simplified block diagram of a system on a chip integrated circuit device according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown in FIG. 1, an integrated circuits comprises multiple locations that may need temperature and voltage sensing. For example, the integrated circuit in FIG. 1 is a SerDes device that includes a receiver and a transmitter, and it also has receiving lanes (e.g., RX Lanes) and transmission lanes (e.g., TX lanes). Sensors 102 and 108 are positioned within a proximity of TX lanes at the receiver end. Sensors 104 and 106 are positioned within a proximity of TX lanes at the transmission end. Sensors 103 and 107 are positioned at the center portion of the integrated circuit. For example, the sensors detect temperature and/or voltage information and send the information to the voltage-temperature (VT) core 101 as current levels. The VT core 101, as described below, is configured to process the current information and generates a digital read out of temperature information. In various embodiments, the sensors are capable of measure temperature from about OC to over 110 C.

It is to be appreciated that the VT core 101 can be integrated to the integrated circuit. In addition to the SerDes device as shown, the VT core 101 can be integrated with other types of devices, such as SerDes device, a DDR register device, a DSP device, a controller device, a microcontroller device, an ASIC device, or others. For example, an integrated communication device (e.g., SerDes device) is configured on a silicon bearing substrate. The device has a transmitter module and a receiver module, both of which are also configured on the silicon bearing substrate. Additionally, the device comprises a phase lock loop module that is also configured on the silicon bearing substrate. A digital logic core is configured on the same silicon bearing substrate as components of communication device. A voltage and temperature sensing module (e.g., the VT core that connects to the sensors) is configured on the substrate as well. An example of the voltage and temperature sensing module is illustrated in FIG. 2 and described below.

FIG. 2 is a block diagram of a sensing device with a multiplexer according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. The voltage-temperature (VT) core 200 in FIG. 2 can be implemented as an integrated sensing device, and as shown receives a plurality of inputs from sensors (e.g., sensors 102-108 in FIG. 1). In a specific embodiment, analog components of the VT core 200 are on regulated power supply that reduces the possibility of introducing jitters.

In various embodiments, the VT core 200 and the sensors shown in FIG. 1 are manufactured using the same processes (e.g., 40 nm process, 28 nm process, etc.) as the integrated circuit that they measure. The sensor inputs are representative of voltage and/or temperature readings in the form of current levels. The multiplexer 206 is a part of the VT core 200 that allows the VT core 200 to selectively process the VT readings from the sensors one at a time.

Depending on the application, the VT core 200 can have a large number of sensors. The selected current information (i.e., representative of temperature and/or voltage) is received by the reference generator 208. For example, the reference generator 208 as shown comprises a comparator and provides an output voltage Vtrip. The reference generator 208 is electrically coupled to the output of the multiplexer 206 and is configured to generate a signal proportional to the current information.

The VT core 200 comprises, among other components, a clock device, which is not shown in FIG. 2. The clock device is configured to generate at least a first clock signal and a second clock signal. The second clock signal is 180 degrees out of phase of the first clock signal. The VT core 200 further comprises delay cores 203 and 204. The first delay core 203 includes a first delay core output, and it is coupled to the clock device to receive the first clock signal. The second delay core 204 has a second delay core output. The second delay core is configured to receive the second clock signal. As shown in FIG. 2, the first delay core 203 is coupled to the second delay core 204 and shares a common feedback voltage (Vcmfb). Delay cores 203 and 204 are both connected to the common feedback signal. Together, the first delay core 203 and the second delay core 204 generate a differential signal that has a common mode representing a temperature reading during the temperature measurement mode, or a voltage reading during the voltage measurement mode. The lower portion of FIG. 2 provides a detailed view of delay core 203. For example, the delay core 204 is similarly configured.

The VT core 200 also includes a common load feedback (CMFB) circuit 211. The CMFB circuit 211 provides the common feedback voltage Vcmfb, which is coupled to the first delay core 203 and the second delay core 204. The CMFB circuit 211 is coupled to a voltage extractor 212. The voltage extractor 212 is also coupled to the outputs of the first delay core 203 and the second delay core 204. For example, the voltage extractor 212 comprises resistors configured in series. Depending on the implementation, the voltage extractor 212 can have different load configurations as well.

A common mode generator circuit 208 is coupled to the common load feedback circuit 211. The common mode generator circuit is configured to operate in a voltage measurement mode or a temperature measurement mode. A load equalizer device 205 is coupled to the second delay core 204 output and the common load voltage extractor 212 as shown.

A comparator device 202 is coupled to the first delay core 203 output and the common load voltage extractor 212. The comparator device 202 is configured to convert a first waveform 210 from the common mode voltage extractor to a second waveform. As shown at the bottom portion of FIG. 2, the first waveform 210 is a triangular waveform. The triangular waveform, as illustrated in FIG. 2, is a function of Vref=Vtrip+i*R. The principle of operation is described in more details below. With the help of the reference generator 208 that provides Vtrip voltage, the triangular waveform is provided from the delay core 203 and contains current information. Reading the triangular waveform and the Vtrip voltage (from the reference generator 208), the comparator 202 is configured to generate a square waveform (not shown in FIG. 2). The square waveform from the comparator 202 and a clock signal are coupled together by the logic gate 201 to generate a pulse width modulated signal 209. The clock signal can be generated by a pulse width generator. In a specific embodiment, the clock signal has a frequency of greater than 2 MHz. For example, the logic gate 201 is an AND gate. The output from the logic gate 201 can be used as a data signal that represents voltage and/or temperature reading of the sensors.

FIG. 3 is a simplified flow diagram illustrating the operation of a sensing device according to embodiments of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. For example, the method illustrated in FIG. 3 can be implemented using the exemplary device shown in FIGS. 1 and 2, and various steps may be added, removed, repeated, modified, replaced, and/or overlapped. The method starts at step 301. For example, a temperature and voltage sensing device is started and initiated at step 301. For example, certain variables and/or parameters of the sensing device may be calibrated and/or adjusted at step 301. At step 302, current information from a remote sensing site within the integrated circuit device is transferred to a reference generator. In an embodiment, a multiplexer is used to select different current information from a number of sensing devices. The current information can be from one of many sensors that are connected to a VT core, which includes a reference generator. For example, the reference generator is configured to provide a reference voltage that can be used. As described above, the remote sensing site is provided on a spatial portion of one of a plurality of integrated circuit modules provided on the integrated circuit device. For example, the current information is a variable across an operating range of the integrated circuit device.

At step 303, the current information is received by the reference generator. The reference generator is configured to generate a signal proportional to the current information using the reference generator, at step 304. For example, the signal is a function of a reference voltage, current information from the sensing site, and known resistance (or impedance) value of one or more electrical components of the VT core. At step 305, the generated signal is transferred to a common mode feedback circuit, which is coupled to a first delay core and a second delay core. For example, the connections between the common feedback circuit and the delay cores are illustrated in FIG. 2. At step 306, an average voltage of a period waveform is adjusted using the generated signal at the common mode feedback. For example, the average voltage of the period waveform is a function of the reference voltage and current information received from the sensing site. The periodic waveform is converted to a PWM signal that is representative of the current information at a comparator device, at step 307. For example, the PWM signal can be generated by using the period waveform and a clock signal. The period waveform can be a triangular waveform, a square waveform, or a sinusoidal waveform. The PWM signal, depending on the need, may be transferred to a remote device that is not a part of the integrated circuit.

The PWM signal can be processed and used to provide digital information that represents temperature and/or voltage information embedded in the current information. In a specific embodiment, the pulse width modulated signal is received, and the pulse width modulated signal is used in a counter device to output digital information representative of the current information. As described above, the current information is associated with a temperature or a voltage of the remote sensing site. In an implementation, the pulse width modulated signal is received and processed by a low pass filter device.

In various embodiments, a calibration process is used to provide temperature calibration and measurement. During the calibration mode (which may be necessary as a one-time setup), the current reading from the sensor is calibrated to temperature reading. Running the constant current source at known current level and obtain a current reading from the sensor at a known temperature, the relationship between current reading and the temperature reading is determined. For example, a ratio (e.g., or referred to as “gain”) between the current (or other voltage, delay) reading and the temperature level is determined and stored for later measurements. When measuring the temperature reading, the ratio is multiplied with a temperature difference from a reference temperature. For example, the following formula is used:

Temp=Tc+Gain*{Delay2−Delay1}

Voltage calibration and measurement processes are performed similarly as the temperature calibration. A ratio (or “gain”) between current reading and the voltage level is determined and stored for later measurements. When measuring the voltage reading, the ratio is multiplied with a voltage difference from a reference voltage. For example, the following formula is used:

Voltage=1V+Gain*{Delay2−Delay1}

It is to be appreciated that the arrangement and implementation of temperature sensors illustrated in FIGS. 1-3 can provide accurate reading, the method of using temperatures is an important aspect as well. In various embodiments, the present invention provides techniques for quickly calibrating and determining temperature by relying on known relationship between electrical properties and temperature.

As explained above, temperature sensors are important in ensuring proper operation conditions for controls. For example, the integrated circuit device shown in FIG. 1 utilizes many temperature sensors so that temperatures at different location can be determined as needed. It is to be appreciated that the temperature sensor device in FIG. 2 is capable of determining temperature and providing the temperature reading quickly. But it is to be understood that it is important to have both good temperature sensing hardware and temperature sensing techniques. The temperature sensing techniques described below can be used in conjunction with the temperature sensing device in FIG. 2 and other temperature sensing systems and devices as well.

For temperature sensor readings to be useful and reliable, temperature sensors are calibrated before use. According to conventional techniques, calibrating temperature sensors requires temperature measurements at two or more temperatures. Unfortunately, calibration at two or more temperatures is a time consuming process. To measure an integrated circuit device or a chip at two temperatures, it is necessary to change the temperature of the subject (i.e., the integrated circuit) of temperature measurement in order to measure it at a second temperature. It often takes a lot of time to change the temperature (e.g., controlled heating up or cooling down) of a subject device, thereby increasing the manufacturing time, which translates to lower manufacturing throughput and higher cost, as manufacturing time is a considerable portion of the integrated circuit chip production cost.

According to embodiments of the present invention, temperature sensors can be calibrated with one temperature measurement, thereby reducing manufacturing costs. During the temperature determination process, values based on electrical characteristics are used to calibrate temperature sensor. More specifically, embodiments of the present invention use a value, current proportional to absolute temperature (IPTAT), to calibrate temperature at a single point. Among other things, the IPTAT value can be changed using one or more control switches. For example, IPTAT is sometimes referred to as Inversely Proportional to Absolute Temperature. In a specific embodiment, a control module is use to cause changes in IPTAT value. It is to be appreciated that the IPTAT value can be referred to in other terms as well. In a specific embodiment, IPTAT is a physical quantity whose value is equal to k*T*ln(M)/R, where “k” is Boltzmann's constant, “T” is absolute temperature in Kelvin, “ln” is natural logarithm, “M” is a design constant, and “R” is the resistance value of a resistor. For example, the design constant M is derived based on the electrical and physical characteristics of the underlying integrated circuit and/or the temperature sensor.

It is to be appreciated that IPTAT here is used as a reference value, which is used for calibration purpose. For temperature calibration, other reference values, or code reflecting the values, can be used as well. In certain applications, it might be impractical to measure the IPTAT value. And in these applications, code values related to the temperature sensor calibration can be used. Depending on the application, code values can be more robust than the IPTAT, which is related to current measurement. For example, to calibrate the temperature sensor, one way is to change the IPTAT value by using the control switch to change one or more parameters of the sensor and/or the underlying device, at temperature T0.

For example, a new IPTAT value, IPTAT1, corresponds to a new temperature (or a new temperature equivalent). Similarly, a new code value, Code1, can also be used to correspond to a new temperature (or new temperature equivalent), where a code value is used to reflect one or more characteristics of the temperature sensor and/or underlying device.

FIG. 4 is a simplified diagram illustrating a temperature sensor system according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. As shown in FIG. 4, the temperature sensor system comprises a temperature sensor 401, a processor 403, and the control module 402. In various implementations, the temperature sensor 401, a processor 403, and the control module 402 are implemented as a part of the integrated circuit devices whose temperature is to be monitored.

The temperature sensor 401, as the name suggests, is configured to take temperature readings as needed. The processor 403 is configure to process the temperature sensor readings, perform temperature calibration, and generate and use a line equation for temperature determination. As described below, temperature reading can be determined by using the line equation and value(s) associated with electrical characteristics (e.g., voltage, current, delay, and/or others). The control module 402 is configured to switch one or more operating parameters associated with the temperature sensor. In a specific embodiment, the control module 402 is capable of causing changes in IPTAT value. For example, the control module 402 is connected to a IPTAT current generator. It to be appreciated that temperature sensor 401, a processor 403, and the control module 402 can be integrated as a single unit (e.g., a part of an integrated temperature sensor) and/or implemented using various types of hardware module. Additional modules may be used as well. For example, the temperature sensor system in FIG. 4 may additionally include memory storage device that stores temperature calibration values, IPTAT values, line equations, temperature calibration and measurement instructions (executable by the processor 403).

FIG. 5 is a simplified flow diagram illustrating a process for calibrating a temperature sensor according to an embodiment of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. For example, various steps may be added, removed, repeated, modified, replaced, rearranged, and/or repeated, which should not unduly limit the claims.

For the purpose of temperature sensor calibration, an initial IPTAT value, IPTAT₀ is to be determined. For IPTAT₀ value determination, calibration temperature T₀ and value(s) associated with electrical characteristics are needed.

At step 501, a value Q₀ is measure at the calibration temperature T₀. For example, the calibration temperature can be near room temperature, thereby allowing the integrated circuit to quickly reach T₀ for quick measurement. For example, to determine IPTAT₀, voltage, current, and/or delay values corresponding to the calibration temperature T₀ are measured as well. For example, measured value of electrical characteristics (e.g., voltage, current, and/or delay) is denoted as Q₀.

At step 502, the IPTAT₀ is determined at the calibration temperature T₀. As explained above, the IPTAT₀ value can be calculated from known “M” and “R” value, and one or more Q₀ value(s). It is to be appreciated that the IPTAT value determination may involve using other formulae and/or variables as well.

For calibration to work, a second IPTAT value, IPTAT₁, is to be determined. As explained below, multiple (e.g., 2) IPTAT values are needed to generate a linear equation that can be used for later temperature determination. To cause the IPTAT value to change from IPTAT₀ to IPTAT₁, control switches can be used to change one or more electrical characteristics (e.g., voltage, current, delay, and/or others). At step 503, the IPTAT value is changed from IPTAT₀ to IPTAT₁, and corresponding current is changed accordingly. As mentioned above, a control module may be used to cause changes in the IPTAT value. The change from IPTAT₀ to IPTAT₀ can be made quickly and within a time period the temperature is still at (or very close to) temperature T₀. For the purpose of calibration, an equivalent temperature T₁ corresponding to the IPTAT₁ is determined.

At step 504, a new temperature T₁ is determined. As explained above, the actual temperature corresponding to IPTAT₁ and current is substantially the same as T₀. However, for the purpose of temperature calibration, current value and IPTAT₁ correspond to the new temperature T₁. Even though the actual or operating temperature has not changed, temperature sensor is operating at a new “equivalent” temperature because of the change of IPTAT. Similarly, if code value is used instead of IPTAT, the equivalent temperature calculation is performed using the code value.

The new “equivalent” temperature is calculated as below:

T ₁ =T ₀*(IPTAT₁/IPTAT₀)  (Equation 1)

And in case code value is used:

T ₁ =T ₀*(Code₁/Code₀)  (Equation 1A)

Corresponding to the change of IPTAT from IPTAT₀ to IPTAT₁, the value associated with the one or more electrical characteristics Q₁ is measure. For example, Q₁ can be voltage, current, delay, or other value that corresponds to T₁.

At step 506, a gain value “G” of the temperature sensor is determined. More specifically, the gain (“G) of the temperature sensor is calculated using the equation below:

G=(Q ₁ −Q ₀)/(T ₁ −T ₀)  (Equation 2)

At step 507, a line equation is provided. Among other things, the line equation can used to provide temperature reading by reading one or more values corresponding to electrical characteristics. In a specific embodiment, the line equation of the temperature sensor is calculated as:

Q(_(T))=G*(T−T ₀)+Q ₀  (Equation 3)

For example, to obtain a temperature measurement T_(m), Equation 3 and the electrical characteristics can be used. A reading of an electrical characteristics (e.g., voltage, current, delay, and/or others), or Q_(m), that corresponds to actual temperature is determined. The following equation is used to obtain the temperature measurement T_(m):

T _(m) ={Q(T _(m))+G*T ₀ −Q ₀ }/G.  (Equation 4)

It is to be appreciated that temperature can quickly be re-calibrated and determined using Equation 4, as electrical characteristics are typically easier to determine than temperature reading. For example, the method illustrated in FIG. 4 can be implemented using the temperature sensor system in FIG. 4.

To provide an example, temperature calibration is performed using, among other things, the delay characteristic at calibration temperature T_(c):

$I_{1} = {{{IPTAT}\left( {T\; c} \right)} = \frac{{kTc}*{\ln (M)}}{q*R\; 1}}$

At a second IPTAT value, or IPTAT(Tc+ΔT₂) is:

$I_{2} = {{{IPTAT}\left( {{T\; c} + {\Delta \; T_{2}}} \right)} = \frac{{k\left( {{Tc} + {\Delta \; T\; 2}} \right)}*{\ln (M)}}{q*R\; 1}}$

Or changing the calibration code “m” times so that:

$I_{2} = {{{IPTAT}\left( {{T\; c} + {\Delta \; T_{2}}} \right)} = \frac{{m({kTc})}*{\ln (M)}}{q*R\; 1}}$

The temperature change (equivalent) based on “delay2” can by determined by:

${\Delta \; T_{2}} = {T\; c*\left( {\frac{{IPTAT}\left( {{T\; c} + {\Delta \; T\; 2}} \right)}{{IPTAT}\left( {T\; c} \right)} - 1} \right)}$

Similarly, a third IPTAT value, IPTAT(Tc+ΔT₃) is:

$I_{3} = {{{IPTAT}\left( {{T\; c} + {\Delta \; T_{3}}} \right)} = \frac{{k\left( {{Tc} + {\Delta \; T\; 3}} \right)}*{\ln (M)}}{q*R\; 1}}$

Or changing the calibration code “n” times so that:

$I_{3} = {{{IPTAT}\left( {{T\; c} + {\Delta \; T_{3}}} \right)} = \frac{{n({kTc})}*{\ln (M)}}{q*R\; 1}}$

The temperature change (equivalent) based on “delay3” can by determined by:

${\Delta \; T_{3}} = {{Tc}*\left( {\frac{{IPTAT}\left( {{T\; c} + {\Delta \; T\; 3}} \right)}{{IPTAT}\left( {T\; c} \right)} - 1} \right)}$ ${\Delta \; T} = {{Tc}*\left( \frac{I\; 3}{l\; 1} \right)}$ Δdelay=delay3−delay2

And therefore, the temperature change relative to the delay value is:

${TempGain} = \frac{\Delta \; {dela}}{\Delta \; T}$

It is to be appreciated that the use of gain factor and linear equation to obtain temperature reading is an interpolation process, who error is characterized by Equation 5 below:

Error=Delay(T)−{Gain_(1pt)×(T−Tc)+Delay(T)|_(T=Tc)}  (Equation 5)

FIG. 6 is a simplified graph illustrating one point error calculation according to embodiments of the present invention. This diagram is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications.

As explained above, one-point temperature calibration process can more efficient and cost-effective compared to conventional two-point calibration processes. Tables below are provided to compare the temperature determined by one-point calibration process according to an implementation of the present invention to temperature determined using conventional two-point calibration technique.

Table 1 below shows junction temperature calculation from chamber temperature and power consumption

TABLE 1 Junction Temperature Calculation from Chamber temperature and Power Consumption Chamber Temp [° C.] Chip Power [W] ΔT [° C.] Junction Temp [° c.] −9.8 1.842 13.44 3.64 −0.1 1.877 13.70 13.60 10.2 1.985 14.49 24.69 20.3 1.923 14.04 34.34 27 2.114 15.43 42.43 40.1 1.975 14.42 54.52 50 2.032 14.83 64.83 59.9 2.174 15.87 75.77 70 2.120 15.48 85.48 79.6 2.265 16.53 96.13 89.9 2.320 16.93 106.83

As shown in Table 1, the ambient chamber temperature is adjusted, and power is measure. Then the junction temperature is calculated. For example, the equivalent temperature is calculated using the techniques according to embodiments of the present invention.

In comparison, conventional two-point temperature calibration requires a change in junction temperature, as illustrated in Table 2 below:

TABLE 2 Junction Temp [° C.] Delay Temp Error 3.64 43.75272727 3.64 0.00 13.60 51.32412121 14.86 1.26 24.69 59.26787879 26.64 1.94 34.34 65.47393939 35.83 1.50 42.43 69.94230303 42.45 0.02 54.52 77.01721212 52.94 −1.58 64.83 86.26424242 66.64 1.81 75.77 93.58739394 77.50 1.73 85.48 100.2278788 87.34 1.86 96.13 106.0615758 95.98 −0.15 106.83 113.3847273 106.83 0.00

In a conventional two-point calibration process, junction temperature is changed and the corresponding delay is measured. By using the relationship between the delay value and the junction temperature, gain and offset values for the system can be determined for the two-point calibration method. The gain and offset values, once determined, provide a basis for the line equation associated with the temperature sensor system. The line equation can then be used to determine junction temperature value.

Table 3 illustrates a process of using code value to perform one-point temperature calibration:

TABLE 3 1Point Calibration Code Equivalent Temp [° C.] Delay (ns) 0 0 1 0 12.39 49.33818182 0 0 1 1 27.41 58.70933333 0 1 0 0 (Default) 42.43 69.94230303 0 1 0 1 57.46 79.12727273 0 1 1 0 72.48 89.49139394 0 1 1 1 87.50 99.3590303 1 0 0 0 102.52 110.4678788 1 0 0 1 117.54 119.5907879 Gain1Point Offset1Point 0.673 40.78

As illustrated in Table 3, calibration code value is changed. Based on the change in calibration code value, the equivalent temperature value is determined. The delay value (measure in nanosecond) is also measured. Using the calibration code value, equivalent temperature, and delay value, gain and offset value for the one point calibration equation can be determined.

Table 4 below illustrates using the one-point calibration equation determined from Table 3 to determine junction temperature:

TABLE 4 Junction Temp [° C.] Temp [° C.] Error [° C.] 3.64 4.42 0.77 13.60 15.67 2.06 24.69 27.47 2.78 34.34 36.69 2.36 42.43 43.33 0.90 54.52 53.84 −0.67 64.83 67.58 2.75 75.77 78.47 2.70 85.48 88.33 2.86 96.13 97.00 0.87 106.83 107.88 1.05

For example, the gain value and offset value determined from Table 3 is used to provide a line equation, which is then used to provide junction temperature information based on other known values. It is to be appreciated that while the junction temperature determined using the linear equation determined using an one-point calibration method is slightly different from the actual temperature, the amount of error is relatively small and acceptable for most of the application where a temperature reading is needed.

It is also to be noted that the amount of error from an exemplary one-point calibration method is comparable to the amount of error from a conventional two-point calibration method, as illustrated in Table 5 below:

TABLE 5 Error_2PointCalibration [° C.] Error_1PointCalibration [° C.] 0.00 0.77 1.26 2.06 1.94 2.78 1.50 2.36 0.02 0.90 −1.58 −0.67 1.81 2.75 1.73 2.70 1.86 2.86 −0.15 0.87 0.00 1.05

While the above is a full description of the specific embodiments, various modifications, alternative constructions and equivalents may be used. Therefore, the above description and illustrations should not be taken as limiting the scope of the present invention which is defined by the appended claims. 

What is claimed is:
 1. A method for temperature calibration, comprising: measuring a first temperature on an integrated circuit using a temperature sensor; determining a first delay electrical characteristic; determining a first reference value for the integrated circuit at the first temperature, the first reference value based on a first delay electrical characteristic; measuring a second delay electrical characteristic for the integrated circuit; determining a second reference value for the integrated circuit based on the second delay electrical characteristic and a second temperature, the second temperature being an equivalent temperature calculated based on the second delay electrical characteristic; determining a gain value from the first reference value and the second reference value; and generating a line equation using the gain value.
 2. The method of claim 1 further comprising: measuring a third delay electrical characteristic comprising a differential signal from a delay core; and determining a third temperature using the third delay electrical characteristic and the line equation.
 3. The method of claim 1 wherein the first reference value is proportional to the first temperature.
 4. The method of claim 1 wherein the second temperature is based on a proportionality between the first delay electrical characteristic and the second delay electrical characteristics.
 5. The method of claim 1 further comprising generating the second reference value using one or more control switches.
 6. The method of claim 1 wherein the gain value is a ratio between a changing electrical characteristic and a corresponding changing temperature.
 7. The method of claim 1 wherein the first reference value comprises a current proportional to absolute temperature value described by equation IPTAT=K*T*ln(M)/R, where K is Boltzmann's constant, T is absolute temperature in Kelvin, M is a design constant, and R is a resistance value.
 8. The method of claim 1 wherein the integrated circuit comprises a Serializer/Desrializer (SerDes) device, a DDR register device, a DSP device, a controller device, a microcontroller device, or an ASIC device.
 9. The method of claim 1 wherein: the delay core comprises a first delay core and a second delay core receiving a common feedback voltage; and the differential signal is from the first delay core and the second delay core.
 10. A method for temperature calibration, comprising: measuring a first temperature on an integrated circuit using a temperature sensor; determining a first calibration code for the integrated circuit at the first temperature; measuring a second delay electrical characteristic for the integrated circuit; determining a calibration code for the integrated circuit based on the second delay electrical characteristic and a second temperature, the second temperature being an equivalent temperature calculated based on the second delay electrical characteristic; determining a gain value from the first calibration code and the second calibration code; generating a line equation using the gain value; and determining one or more device characteristics using a third calibration code.
 11. The method of claim 10 wherein the temperature sensor is configured to determine delay values.
 12. The method of claim 10 further comprising storing calibration codes.
 13. The method of claim 10 further comprising transmitting temperature values.
 14. The method of claim 10 the one or more device characteristics include equivalent temperature, delay value, and/or gain value.
 15. The method of claim 14 further comprising a memory storing characterization data associated with the integrated circuit, the characterization data comprising the design constant.
 16. An integrated circuit device forming using a nanometer-length manufacturing process, the device comprising: a clock device comprising a first clock signal and a second clock signal; a first delay core comprising a first delay core output, the first delay core being coupled to the first clock signal and receiving input of the first clock signal; a second delay core comprising a second delay core output, the second delay core being coupled to the second clock signal and receiving input of the second clock signal, and coupled to the first delay core, the second clock signal being 180 degrees out of phase of the first clock signal; a common load feedback circuit coupled to the first delay core and being coupled to the second delay core through a common mode voltage extractor coupled to the first delay core output and the second delay core output; a common mode generator circuit coupled to the common load feedback circuit, the common mode generator circuit being configured to operate in a voltage measurement mode or a temperature measurement mode; a load equalizer device coupled to the second delay core output and common load voltage extractor; a comparator device coupled to the first delay core output and the common load voltage extractor, the comparator device configured to convert a first waveform from the common mode voltage extractor to a second waveform; a pulse width modulated signal generator coupled to an output of the of the comparator device to output a pulse width modulated waveform; and an input coupled to a reference generator; a multiplexer device coupled to the input of a sensing device; and a plurality of lines configured for transferring information to the sensing device.
 17. The device of claim 16 wherein the first waveform is a triangular waveform and the second waveform is a square waveform.
 18. The device of claim 16 wherein the first delay core and the second delay core generate a differential signal that has a common mode representing a temperature reading during the temperature measurement mode or a voltage reading during the voltage measurement mode.
 19. The device of claim 16 wherein the input is configured to receive current information ranging from about 100 mA to about 1 A.
 20. The device of claim 16 wherein the plurality of lines being numbered from 1 through N, where N is an integer greater than 2, each of the plurality of lines being connect to input of the sensing device through the multiplexer device. 